RU2699390C1 - Method for localization of sources of high emission of conducted interference of a cabinet of a complete device and a device for its implementation - Google Patents

Abstract

FIELD: electrical equipment.

SUBSTANCE: use in the field of electrical engineering and power engineering. Method for localization of sources of high emission of conducted interference in a cabinet of a complete device consists in the fact that voltage of noise emission is measured in power supply circuit of a cabinet of a complete device and frequency regions are determined, where the measured voltage of the noise emission exceeds the specified limits, reducing impedance of the power supply circuit of the complete device cabinet relative to its housing, currents of noise emission are measured in power supply circuits of functional units of the cabinet of the complete device, measured currents of the noise emission are compared by level in the frequency range, where the measured voltage of the noise emission exceeds the specified limits, and the location of the functional units which initiate high voltage of the noise emission in the power circuit of the cabinet of the complete device is localized in the cabinet of the complete device. Total resistance of the power supply circuit of the cabinet of the complete device is reduced with respect to its housing at least by 10 dB below the impedance of the equivalent power supply network.

EFFECT: high reliability of localization of sources of high emission of conductive interference and wider field of application.

3 cl, 5 dwg

Description

The invention relates to the field of electrical engineering and the electric power industry, namely, to localization of sources of increased emission of conducted noise in the cabinets of the complete protection, automation and control devices. They can be used in testing laboratories in the process of bringing interference emissions through the cabinet power supply circuit into compliance with the established regulatory requirements.

Currently, cabinets of complete protection, automation and control devices are widely used at electric power facilities. These devices are subjected to mandatory tests for compliance with the requirements of electromagnetic compatibility (EMC) with measurements of interference emissions in accordance with established methods (GOST 30805.22-2013 (CISPR 22: 2006). "Interstate standard. Electromagnetic compatibility of equipment. Information technology equipment. Radio interference. Industrial standards and measurement methods ”, paragraph 5, Fig. 8).

The known method and device is taken as a prototype, can be used to localize sources of increased emission of conducted noise cabinet of the complete device. The method involves measuring the voltage of industrial radio interference (RMI) on the network terminals of the power port of the cabinet of the complete device using a measuring receiver that provides measurement of the average and quasi-peak values of the noise emission voltage, and the network equivalent, providing 50 Ohm impedance at the measurement point on the network cable plug.

The measured voltage of the ИРП is compared with the established limits (norms) for the corresponding class of technical equipment. In the event that the voltage of the IRP at the network terminals of the power supply port of the cabinet of the complete device exceeds the specified limits, sources of increased interference emission are detected, for example, by sequentially disconnecting (de-energizing) the blocks of the complete device and subsequent measurement of the voltage of the local radiation terminal at the network terminals of the power port of the cabinet. According to the results of analysis and comparison of the latest measurements with measurements of the voltage of the IRP in the original circuit of the cabinet of the complete device, it is possible to localize the blocks of the complete device with some approximation, which can initiate an increased noise emission voltage in the power circuit of the cabinet of the complete device.

The method is carried out using a device containing a standard network equivalent, from which the cabinet of the complete device is powered, and a measuring receiver.

A disadvantage of the known method and device by which it is carried out is as follows. Firstly, the disconnection of certain functional blocks of the complete device causes a violation of the integrity of the electrical circuitry of the cabinet and the loss of its functionality, which may not be acceptable for any cabinet of the complete protection, automation and control device. Secondly, in the implementation of the technical solution, the subsequent analysis turns out to be rather complicated due to the dependence of the process of noise emission from the cabinet on the layout conditions (location), installation, and modes of interacting functional blocks of the complete device. These factors determine the insufficiently reliable localization process, which limits the application of the known method and device.

The technical result consists in increasing the reliability of localization and expanding the scope.

The specified technical result is achieved by the fact that in the method of localization of sources of increased emission of conducted noise in the cabinet of the complete device, which consists in measuring the noise emission voltage in the power supply circuit of the cabinet of the complete device and determining the frequency ranges where the measured noise emission voltage exceeds the specified limits, reduce the impedance the power circuits of the cabinet of the complete device relative to its body, measure the emission currents in the power circuits of the function tional blocks cabinet complete device, interference emission measured currents are compared by the level in the frequency region where the measured voltage exceeds the limit interference emission, and localize in the cabinet location complete device functional units that initiate increased interference emission voltage in the power supply circuit of the complete enclosure of the device. Reduce the impedance of the power circuit of the cabinet of the complete device relative to its enclosure, at least 10 dB below the impedance of the equivalent power supply network.

The specified technical result is achieved by the fact that in the device for implementing the method, comprising a cabinet of a complete device with functional units, a measuring receiver, the equivalent of the network, the input of which is connected to the power supply network, and its first output is connected to the power port of the cabinet of the complete device, a multi-channel switch is inserted, and two-terminal devices are introduced into the cabinet of the complete device, the number of which is equal to the number of network terminals of the power port of the cabinet of the complete device, and current probes, the layer of which is equal to the number of functional units of the complete device connected by power cables to the power port of the cabinet of the complete device, each network terminal of the power port of the cabinet of the complete device is connected via a corresponding two-terminal device to the cabinet of the complete device, each power cable of the specified functional blocks of the cabinet is covered by a corresponding current probe , the inputs of the introduced multi-channel switch are connected to the outputs of the current probes and second at the output network equivalent, and output inputted multichannel switch connected to an input of the measuring receiver.

Conducted emission sources are function blocks connected to the power port of the cabinet of the complete device. The conductive (common-mode) noise emission of the cabinet of the complete device, formed by the noise emissions of the functional blocks, closes through the impedance of the network equivalent and returns through a conductor connecting the network equivalent to the cabinet of the complete device. With low impedance of the power circuit of the cabinet of the complete device relative to the housing, the mutual influence of the emission sources is significantly weakened and the levels of the measured emission currents increase. In the claimed technical solution, the measurement of noise emission currents on the internal power circuits of the cabinet of the complete device is carried out without violating its functionality, which ensures high confidence of the source data. This leads to a more reliable subsequent process of localization of the noise emission source, performed by comparing the intensity of the noise emission currents in those frequency regions where the previously measured noise emission voltage exceeded the established limits.

A comparative analysis of the claimed solution with the well-known prototype shows that the claimed technical solution provides greater accuracy and a more reliable process for the localization of noise emission sources, which can be used in testing various designs of complete device cabinets, which leads to its wider application.

In FIG. 1 shows an electrical diagram of a device for implementing the inventive method. In FIG. Figure 2 shows a plot of the noise emission voltage measured in the power supply circuit of a typical relay protection cabinet and circuit breaker control automatics, equipped with two functional blocks; in FIG. 3, 4 - graphs of noise emission currents measured in power supply circuits of the first and second functional blocks, respectively; in FIG. 5 is a block diagram of a two-terminal device connected to the network terminals of the power port of a typical relay protection cabinet and circuit breaker control automatics.

The method for localizing sources of increased emission of conducted noise in the cabinet of the complete device is to measure the noise emission voltage in the power supply circuit of the cabinet of the complete device and determine the frequency regions where the measured noise emission voltage exceeds the specified limits. They reduce the impedance of the power circuit of the cabinet of the complete device relative to its body, measure the emission currents in the power circuits of the functional blocks of the cabinet of the complete device. The measured noise emission currents are compared in terms of the level in the frequency domain where the measured noise emission voltage exceeds specified limits. The location of the functional units initiating the increased interference emission voltage in the power supply circuit of the cabinet of the complete device is localized in the cabinet of the complete device.

A device for localizing sources of increased emission of conducted noise contains: the equivalent of network 1, connected by an input to the power supply network; cabinet 2 of the complete device with functional blocks 3, 4, 5 and current probes 6, 7, 8, covering the power cables of the functional blocks 3, 4, 5 connected to the power port 11 of the cabinet 2; a multi-channel switch 9 and a measuring receiver 10. The power supply port 11 of the cabinet 2 of the complete device is connected by a power cable to the first output of the network equivalent 1, the cabinet 2 is connected to the grounded housing equivalent of the network 1. The second output is equivalent to network 1 and the outputs of current probes 6, 7, 8 are connected to the corresponding inputs of the multi-channel switch 9, the output of which is connected to the input of the measuring receiver 10.

During the measurement of noise emission currents, the network terminals (L) and (N) of the power supply port 11 of the cabinet 2 are connected through the corresponding two-terminal blocks of the unit 12 to the cabinet body 2.

The process of localization of sources of interference emission is initiated when testing the cabinet of the complete device for interference emission. During the test, cabinet 2 is powered by the equivalent of network 1, which provides a stable impedance of 50 Ohms at the measurement point on the cabinet’s power cable. First, the multi-channel switch 7 is set to the position where the input of the measuring receiver 6 is connected to the second output of the network equivalent 1. In this case, all unused inputs are connected to matching loads with a resistance of 50 Ohms. Using the receiver 6, the noise emission voltage coming from the second output of the network equivalent 1 is measured and the frequency characteristics of the average and quasi-peak values of the noise emission voltage are measured. The measurement results are compared with the limits established by GOST 30805.22-2013 for the corresponding class of technical equipment. Frequency regions where the interference emission voltage exceeds the corresponding limits are determined.

Then, the network clamps (L) and (N) of the power supply port 11 of the cabinet 2 are connected through the corresponding two-terminal blocks of the unit 12 to the cabinet body 2. The position of the switch 7 is changed and the input of the measuring receiver 6 is connected alternately to the outputs of the current probes 6, 7, 8. The emission currents are measured in the power supply circuits of the functional blocks 3, 4, 5 and the frequency characteristics of the average and quasi-peak values of the noise emission currents are taken.

Corresponding values of noise emission currents are compared among themselves at the maximum levels recorded in the vicinity of frequencies where the voltage of the noise emission exceeded the established limits. Based on the results of comparing the noise emission currents, the location of one or more functional units that dominate the emission of conducted noise in the power supply circuit of the cabinet 2 of the complete device is determined (localized). The subsequent analysis clarifies how large the influence of the layout and installation of these units on the process of interference emission is made, and the final conclusion is made about the specific source of increased emission of conducted interference cabinet 2 of the complete device.

An example of practical implementation. To localize the sources of conducted noise emission in a typical cabinet of a complete relay protection device and circuit breaker control automation, consisting of two functional blocks, the following were used:

эквивалент сети ESH2-Z5;

equivalent network ESH2-Z5;

токовый пробник EZ-17;

current probe EZ-17;

измерительный приемник ESR-7;

ESR-7 measuring receiver;

блок 12 (фиг. 5), содержащий два резистивно-емкостных двухполюсника (R=2 Ом, С=1 мкФ), первые полюса которых подключены к сетевым зажимам соответственно L и N порта 11 электропитания шкафа 2, а вторые полюса - подключены к корпусу шкафа 2.

block 12 (Fig. 5) containing two resistive-capacitive bipolar (R = 2 Ohm, C = 1 μF), the first poles of which are connected to the network terminals L and N, respectively, of the power supply port 11 of cabinet 2, and the second poles are connected to the housing cabinet 2.

On the frequency characteristic of the noise emission voltage in the power supply circuit of a typical cabinet of the complete device (Fig. 2), taken using a measuring receiver with a quasi-peak detector, the frequency range in the vicinity of 210 kHz is selected, where the quasi-peak value exceeds the noise emission voltage norm for class A - 80 dBμV. In the same frequency range, the maximum quasi-peak values of noise emission currents in the power supply circuit of the first functional unit (Fig. 3) are 54 dBmA, and in the power supply circuit of the second functional unit (Fig. 4) - 15 dBmA. Therefore, the source of increased cabinet noise emission voltage is the first functional unit, in which the noise emission current in the vicinity of 210 kHz is significantly higher (39 dB) than the second functional unit.

For interference emission currents of the functional blocks, a limit level can be set, which is determined based on the limit of 80 dBμV set for the interference emission voltage, minus 34 dBOm in accordance with the value of the impedance of the network equivalent of 50 Ohms, which is 46 dBμA. According to the characteristic of FIG. 3, the noise emission current of the first functional block exceeds the specified limit in the vicinity of frequencies of 210 kHz and 315 kHz. Therefore, under adverse conditions of installation and installation of the first functional unit, the probability of increased voltage of interference emission in the vicinity of the frequency of 315 kHz is high.

Thus, the proposed technical solutions (method and device) provide a selective and reliable process of localization of noise emission sources, which is carried out without violating the initial configuration and functionality of the complete device and little depends on the conditions of installation and installation of functional blocks distributed in the cabinets of the complete device, which leads to a wider their application than known solutions.

Claims (3)

1. The method of localization of sources of increased emission of conducted noise in the cabinet of the complete device, which consists in measuring the voltage of the interference emission in the power supply circuit of the cabinet of the complete device and determining the frequency areas where the measured voltage of the interference emission exceeds the specified limits, characterized in that they reduce the total resistance of the power supply circuit the cabinet of the complete device relative to its housing, measure the emission currents in the power circuits of the functional blocks of the cabinet a device for interference emission measured currents are compared by the level in the frequency region where the measured voltage exceeds the limit interference emission, and localize in the cabinet location complete device functional units that initiate increased interference emission voltage in the power supply circuit of the complete enclosure of the device. 2. The method according to p. 1, characterized in that they reduce the impedance of the power circuit of the cabinet of the complete device relative to its cabinet body, at least 10 dB below the impedance of the equivalent power supply network. 3. A device for implementing the method, comprising a cabinet of a complete device with functional units, a measuring receiver, the equivalent of a network whose input is connected to the power supply network, and its first output is connected to the power port of the cabinet of the complete device, characterized in that a multi-channel switch is inserted, and the case of the complete device introduced two-pole, the number of which is equal to the number of network terminals of the power port of the cabinet of the complete device, and current probes, the number of which is equal to the number of of complete units of the complete device connected by power cables to the power port of the cabinet of the complete device, with each network terminal of the power port of the cabinet of the complete device connected via a two-terminal device to the cabinet of the complete device, each power cable of these functional blocks of the cabinet of the complete device is covered by a corresponding current probe, inputs the entered multichannel switch connected to the outputs of the current probes and the second output at equivalent network, and inputted multichannel output switch connected to an input of the measuring receiver.

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